Electric power transmission system



y 1940. E. F. w. ALEXANDERSON 08,183

ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 10 Sheets-Sheet l Inventcbr: Ernst F. W Alexanderson His Attorney.

y 16, 1 E. F w. ALEXANDERSON ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 10 Sheets-Sheet 2 LT L P; Inventor: Ernst F. W. Alexanderson Zia Attorney.

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ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 10 Sheets-Sheet 3 I I I I I I w) f I Inventor Ernst F. W. Alexanderson,

His Attorney.

July 16, 1940. E. F. w. ALEXANDERSON 2,203,183

ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 10 Sheets-Sheet 4 Inventor: Ernst F. W. Alexanderson,

by V%7 M H is Attorney y 1940- E. F. w. ALEXANDERSON 2,208,133

ELECTRIC POWER TRANSMISSION SYSTEM 10 Sheets-Sheet 5 Filed Nov. 5, 1938 Inventor Ernst PW. Alexanderson His Attorney.

E. F. w. ALEXANDERSON ,208,183

ELECTRIC POWER TRANSMISSION SYSTEM July 16, 1940.

Filed NOV. 5, 1938 10 Sheets-Sheet 6 wmmi Inventor Ernst F. WAIexanderson, by 7 Hi5 Attorney.

y I 1940. E. F. w. ALEXANDERSON 2,208,183

ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 l0 Sheets-Sheet 7 P Q -R -.s -T g Inventor a Ernst F W.Ale x-ander-son, 20 4o 60 an M0 CURRENT M/AMPERfJ. y J

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y 1940. E. F. w. ALEXANDERSON ,2 8,183

ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 10 Sheets-Sheet 8 L v I Fig.3b.

Inventor Ernst FW. Aiexanderson,

is Attorney.

July 16, 1940.

E. F. W. ALEXANDERSON Filed Nov. 5, 1958 10 Sheets-Sheet 9 7 23 1% a N N N m N 23 I i m N I m :5 a! Jfi g 3: 1 -1w "1 Bwsfl Fwwi I I W L I i J .J g 11} Inventor": Ernst F. W. Alexanderson, b 7

His Attorney.

10 Sheets-Sheet 1O 8 an m F J S l. P g Q 0 v3 m td ll 9 a SK v x 5 II: 3% I Rm QM @sm gm $m w y 1940- E. F. w. ALEXANDERSON ELECTRIC POWER TRANSMISSION SYSTEM Filed Nov. 5, 1938 His Attorney.

Patented July 16, 1940 I UNITED STATES PATENT orrica ELEUIRIG PQWER TRANSMISSIQN SYSTEM Ernst F. W. Aiexanderson, Schenectady, N. Y

assignor to General Electric Company, a corporation of New York Application November 5, rest. Serial No. 239,159

85 Glaims.

inductive and capacitive reactance phenomena, simplicity and ease of operation and the nonexistence of the stability problem.

Heretofore it has been proposed to use electric valves in high voltage systems for transmitting power by means of direct current systems because of themany inherent advantages obtainable by the use of electric valves. Some of the advantages afforded by the use of electric valves in systems of this nature are low initial cost, simplicity of control' and facility of operation.

The "I'hury system of transmission of electric current by. means of constant current direct current has been found to operate very satisfactorily in Europe, but has always been subject to the necessity of rotating machines with mechanical commutators at both the generating and receiving stations. While the Thury system has been satisfactory from the standpoint of a transmission system, it has left muchto be desired in connection with distribution applications. The Thury system'has always been considered as a transmission development and has not offered the flexibility of operation and ease of control which are necessary and important to systems which are required to function both as transmission systems and as distribution systems. In accordance with the teachings of my invention described hereinafter, I provide new and improved electric power transmission systems for the transmission of power by means of direct current and which obviate many of the disadvantages present in the prior art arrangements.

It has also been proposed heretofore to transmit power by means of direct current of constant value. Electric valve apparatus has been used in systems of this nature. However, it is appreciated that in systems of this kind the relatively large power losses at low values of power .are objectionable; These losses remain (c1. iii-en substantially constant throughout the entire range of power transmitted due to the fact that the current remains constant. In accordance with the teachings of my invention described hereinafter, I provide a new and improved elec trio valve system for transmitting power by,

means of direct current and in which the above mentioned disadvantage is obviated.

It is an object of. my invention to provide new and improved electric power transmission systems.

It is another object of my invention to provide new and improved electric systems for transmitting power by means of direct current.

It is a further object of my invention to provide new. and improved electric power transmission systems for transmitting power by means of direct current at variable power levels.

It is a still further object of my invention to provide new and improved electric power systems for transmitting power by means of direct current at'different predetermined current levels.

It is a still further object of my invention to provide new and improved electric power transmission systems for transmitting power by means of direct current at a predetermined voltage for a definite range of power transfer and for effecting transfer'of power at substantially constant current when the system demands power in excess of the range.

In accordance with the illustrated embodiments of my invention, I provide new and improved electric power transmission systems in which power is transmitted by means of high voltage direct current and which are capable of .transmitting power between alternating current circuits and direct current circuits, or between alternating current systems through translating apparatus comprising a direct current circuit or link. Moreparticularly, I provide a direct current electric power transmission system for transmitting power at diiferent predetermined power levels depending upon the load requirements of the associated system, or systems. By selection or adjustment of the power level at which power is transmitted, the systems may be operated at high efficiencies irrespective of the amount of power being transmitted.

In one of the embodiments of my invention,

I provide 'a direct current power transmission which are connected to transmit energy to or re- The power lever at which power is transmitted may be controlled by controlling the electric valve means. For example, the direct current terminals of the rectifiers and the inverters may be controlled in accordance with predetermined controlling influences to control the power level. Short circuiting switches may be connected across the direct'current terminals of the rectifiers and inverters to render inoperative the associated electric valve circuit to control the power level. Additional isolating switches may be coni, nected to the associated alternating current circuits to disconnect completely the rectifiers and the inverters.

In accordance with another illustrated embodiment of my invention, I provide a new and. improved high voltage direct current power transmission system for transmitting energy from a source of power to an alternating current load circuit. The system is applicable for energizing an isolated alternating current load circuit, that is, an alternating current load circuit which is not fed by a synchronous system. This type of transmission system is sometimes referred to as a stub-end feed. In systems of this nature I provide an improved transmission circuit which controls not only the voltage. but the frequency of the alternating current load circuit. The voltage and frequency are maintained by means of a synchronous dynamo-electric machine, or a synchronous condenser, the excitation of which is varied in response to load to maintain the voltage and frequency at substanially constan predetermined values.

In another illustrated embodiment of my invention, I provide an improved electric valve system for energizing a direct current transmis-. sion circuit, and which may be employed for the transmission of electric power between a constant voltage alternating current circuit and a, direct current circuit, or may be employed for the transmission of power between two constant voltage alternating current circuits over a direct current ,transmission line. The transmitting station comprises a plurality of serially connected rectifiers, each of which comprises an electric valve means of the controlled type having control members for controlling the conductivities thereof. Power is transmitted at substantially constant voltage over a predetermined range of power transfer, and when the power tends to exceed a definite predetermined value the energization of the control membersv is varied to transmit power at a substantially constant power level. The receiving stations each include a plurality of serially connected electric valve inverters each comprising electric valve means of the controlled type having control members for controlling the conductivity thereof. The power transmitted by the various electric valve inverters is controlled by means of circuits which are operated in response to the frequency of the associated alternating current load circuit. The frequency responsive means also tends to maine tain the voltage of the alternating current load. circuit at a substantially constant value.

aacaiss In accordance with the illustrated embodiment of another feature of my invention, I provide a direct current transmission system in which power may be transmitted at different predetermined values of direct current. That is, the current transmitted over the direct current line is maintained at a predetermined selected value depending upon the power transmitted and the load requirements. The direct current may be adjusted or varied to suit the operating conditions and may be adjusted in response to load to effect a reduction of the power losses of the system when the amount of power transmitted is relatively small. Conversely, the current level may also be increased to supply additional load when the amount of power to be transmitted is increased. The transmitting stations comprise a plurality of serially connected electric valve rectifiers, and each of the receiving stations comprises a plurality of serially connected electric valve inverters. The amount of power transmitted is determined by the current level, the number of serially connected units in operation and the voltage of each of the serially connected units. The current transmitted to the direct current circuits is maintained at a substantially constant value by controlling the excitation of an alternating current generator which supplies the several electric valve rectifiers. Means are provided to render operative and inoperative the several electric valve rectifiers to control the power level at which power is transmitted to the respective receiving stations. That is, means responsive to a predetermined controlling influence such as the power transfer selectively shunt the direct current terminals of the electric valve rectifiers to control the voltage limits, and hence the power limits, through which power may be transmitted to the load circuits for a definite preselected value of the direct current. Automatic means, responsive to the amount of power transmitted by the system, are provided to select the current level at which power is transmitted. At the receiving stations, I provide a plurality of serially connected electric valve inverters connected in series.

relation with each other for transmitting power from the direct current circuit to an associated alternating current load circuit. The serially connected electric valve inverting apparatus at the receiving stations are arranged to control 0 the power transmitted to the load circuit. A synchronous condenser is connected to the load circuit to maintain the voltage at a substantially constant value, and I provide means for controlling the conductivity of the auxiliary electric valve circuit to control the amount of power transmitted to the load circuit. The auxiliary electric valve circuit is responsive to the frequency of the load circuit. Additional means is provided to disconnect and connect the various serially connected units at the receiving station to transmit power at a predetermined voltage to the load circuit irrespective of the current level at which power is transmitted over the direct current circuit. 7

In accordance with a still further feature of the illustrated embodiments of my invention,'I provide a new and improved electric power trans mission system of the constant current or variable current-level system in which the transmitting and receiving stations are all connected in series relation with each other. That is', the current of the "direct current transmission line flows through all the transmitting and receiving units. In this respect the systems disclosed may be deaaoaiea fined as series constant current or series variable current-level direct current power transmission systems.

In accordance with another feature of the illustrated embodiments of my invention, I provide a new and improved high voltage direct current power transmission system for energizing an isolated alternating current load circuit, that is, for energizing a load circuit which is not con nected to a synchronous alternating current system. The voltage and'frequency of the alter hating current load circuit is controlled by means of a synchronous dynamo-electric machine con nected to the alternating current load circuit. The field excitation of the synchronous machine is varied in accordance with the load current in order to maintain the frequency substantially constant, and the direct current voltage of the transmission line is varied in response to the frequency of the alternating current load circuit For a better understanding of my invention, reference may be had to the following descrip tion taken in connection with the accompanying drawings and its scope will be pointed out in the appended claims. Figs. la-ld diagrammatically illustrate an embodiment of my invention as applied to a direct current transmission system for transmitting power between two constant volt- .age alternating current circuits and in which the transmitting and the receiving stations each comprise a plurality of serially connected electric valve rectifiers and inverters, respectively. Figs. 2a and 2b diagrammatically illustrate another embodiment of my invention as applied to a direct current transmission system in which power is transmitted between two constant voltage alternating current circuits and in which current is transmitted at substantially constant voltage for a predetermined range of power transfer and power is thereafter transmitted at constant power. Figs. 2c and 2d represent certain operating characteristics of the arrangements shown in Figs. 2a and 2b. Figs. 3a-3b diagrammatically illustrate an embodiment of my invention as applied to a direct current transmission system in which electric power is transmitted at predetermined different current levels. Fig. 4 represents operating characteristics of the arrangement shown in Figs. Ila-3b. Fig. 5 diagrammatically illustrates a high voltage direct current power transmission system embodying a number of the aforementioned transmitting and receiving units, such as the arrangements shown in Figs. 3a-3cl. Figs. 6 and 7 diagrammatically illustrate other embodiments of my invention as applied to a direct current transmission system in which the magnitude of the direct current voltage, and hence the power thereof, is controlled in accordance with the frequency of the alternating current load circuit.

Referring now to Figs. 1a-1d, which together constitute a complete transmitting and receiving system, I have shown my invention as applied to a high voltage, direct current electric power transmission system for transmitting power between a constant voltage, alternating current circuit I and a constant voltage, alternating current circuit 2 through a direct current transmission line 3. It is to be understood that the arrangement illustrated in Figs. lat-1d is capable of transmitting power between the alternating current circuits I and 2, and for the purpose of explaining the system, the trans-= mitting apparatus associated with circuit i will be considered as the transmitting station, and

the translating apparatus associated with the re= ceiving apparatus will be considered as the re-= ceiving station. At the transmitting station, I provide a plurality of serially connected electric valve rectifiers il-1, each having direct current terminals 3 and 3 and each being energized from. alternating current circuits til, it, it and i3, respectively. Each of the electric valve rectifiers l-i comprises a plurality of electric valve means t l which are preferably of the type employing an ioniaable medium, such as a gas or a vapor, and each of which comprises an anode 55, a cathode it and a control member or grid it which controls the conductivity thereof.

The alternating current circuit 5 may be energized from any suitable source, such as a dynamo electric machine in which may be of the synchronous type comprising an armature member and a field winding iii which is energized from a suitable source of direct current it. A switch and air core reactances 23 may be connected between the armature l9 and the transmitting station. A step-up transformer 26 may be interposed between the machine it and the translating apparatus if an increased voltage is desired.

As an agency for providing a polyphase system of voltages for energizing the various electric valve rectifiers 4-? to obtain a desired wave form of the direct current transmitted to the transmission line 3, I employ transformers 25 and 26 having primary winding 21, 28 and secondary windings 29, 30; 31, 32 respectively. The primary windings and the secondary windings of transformers 24 and 25 may be arranged to provide a polyphase system at voltages such as twenty-four phase system of voltages. Circuits Ill-I3 are energized from secondary windings 29-32, respectively, and furnish polyphase alternating current to electric valve rectifiers 4-1, respectively. Certain features of the connections of transformer 25 are disclosed and claimed in my copending divisional application Serial No. 321,713, filed March 4, 1940, and which is assigned to the assignee of this application.

It is to be noted that I may employ a plurality of groups of serially-connected electric valve rectifiers. That is, each group may include a number of arrangements such as rectifiers 4-1, all of which may be connected in series relation with each other.

I provide a plurality of control excitation circuits 33 each associated with a different one of the electric valve means M in electric valve rectifiers 4-1. .These excitation circuits serve as arrangements for controlling the conductivities of the electric valves M. The excitation circuits of electric valve rectifiers 4-1 are energized from transformers 34-31, respectively. It will be noted that the transformers 34-31 also supply energy to the cathode heating elements of the electric valves 14 in the electric valve rectifiers 4-1. The excitation circuits 33 may be of any conventional type well known in the art, and for the purpose of illustrating my invention I have shown the excitation circuits 33 as being of the type disclosed and claimed in United States Letters Patent 2,114,828 granted April 19, 1938 upon an application of B. D. Bedford and assigned to the assignee of the present application. Each of the excitation circuits 33 comprises a transformer 33 energized from a suitable phase of the associated transformers i i-31, and a unidirectional conducting device such as a contact rectifier 39 which is arranged to be conable source of current, such as a battery 56, a

nected in series relation with the control grid ll of the associated electric valve M. A suitable switch 40 may be connected between the unidirectional conducting device 39 and the grid I! to impress upon the control grid II a negative unidirectional biasing potential which renders the valve M nonconductive when transformer 38 is not directly connected to grid IT. A resistance 4| is arranged to be connected across the unidirectional conducting device 39 when the switch Ml is in the left-hand position to afford a path for the grid current in the event the uni- .directional conducting device 39 becomes defective. This arrangement of the parallel connected resistance M and the rectifier 39 afiords a relatively low impedance path to the flow of normal grid current and offers a relatively great impedance to the flow of positive ion current. To impress on the control grid IT a negative unidirectional biasing potential, I employ a parallel connected capacitance and a resistance 43. A resistance 44 may be connected in series relation with resistance 4|. Resistance 63 may be of the type having a nonlinear impedance current characteristic, if desired. When the switch 40 is in the left-hand position, the electric valve M is rendered conductive periodically by the voltage supplied by transformer 38. when the switch 40 is in the right-hand position, the electric valve I4 is maintained nonconductive by the negative unidirectional biasing potential appearing across the terminals of capacitance 52. Capacitance 45 is connected across the grid l1 and anode IE to absorb extraneous voltages. The switches 40 of the excitation circuits 33 may be interconnected by means of the gang controller 46. The controller 46 may be actuated by a suitable overload protective means, such as a current responsive relay which automatically throws the switches 50 to the right-hand position to render the electric valve means nonconductive in the event of overload. A suitable inductive reactance t8 may be connected in series relation with the direct current circuit 3.

In order to control the power level at which power is transmitted over the direct current circuit 3, I provide means for controlling the individual electric valve rectifiers 4-7. For example, I provide switches 69 and 50 associated with electric valve rectifiers 5 and 1, respectively, for short circuiting the direct current terminals 8 and 9 to render the electric valves selectively operative and inoperative. As a means for isolating the electric valve rectifiers, I also employ switches 5|, 52 and 53, 55 associated with electric valve rectifiers 5 and l, respectively. The rectiflers 6-4 are arranged to transmit a predetermined amount of power; that is, each is designed to transmit power at different voltages depending upon the voltage of circuit i. In the event the power demanded by the system decreases, certain of the electric valve inverters may be disconnected from the transmitting station to decrease the power level. In order to disconnect certain predetermined rectifying units or groups, I provide a circuit 55 for energizing the actuating coils of switches 49-54. Circuit 55 may comprise a suitcurrent limiting resistance 5'! and a switch 58 having contacts 59 and 60. Switch 58 may be controlled in accordance with a predetermined controlling influence, such as the amount of power transmitted by the direct current circuit 3 to control the number of rectifying units operatively connected at the transmitting station.

The rectifying units 5-1 may be selectively connected and disconnected in order to maintain the direct current transmitted at a substantially constant value or within a predetermined range of values in accordance with the power demanded by the system. Switch 58 may be automatically operated in response to a predetermined controlling influence, such as the power or the current of the direct current circuit 3, in order to obtain this type of control. When contacts 59 are engaged, the rectifying unit 5 is rendered inoperative and when contacts 60 are engaged, rectifying units 5 and 'i are rendered inoperative efiecting corresponding decreases in the power level at which power is transmitted. Switches 5 I54 are arranged to open with a predetermined time delay. Since the actuating coils of the switches for each rectifying unit are energized in series relation, it is desirable to efiect closure of switches 49 and 50 prior to the opening of the associated switches 5|, 52, 53 and 54, respectively.

At the receiving station associated with the alternating current circuit 2, I provide a plurality of serially connected inverting circuits or units Gl-Gt each having direct current terminals 65 and 66. The inverting units 6 I65 are connected in series relation with each other and are connected to be energized from the direct current circuit 3. Each of the inverting units iii-6t. comprises a plurality of electric valve means 61 which are also preferably of the type employing an ionizable medium, such as a gas or a vapor, and each is controlled by means of an associated control or excitation circuit 68 which may be the same as excitation circuits 33 described above. The excitation circuits 68 at the receiving station may also be operated by a gang controller to render the electric valves 61 nonconductive when desired. The electric valve inverters 6|6t are connected to the alternating current circuit 2 through alternating current circuits 69-12, respectively. Transformers l3 and It are connected between circuits 69-12. and alternating current circuit 2 and are provided with primary windings l5, l5; ll, 18 and secondary windings l9 and 80, respectively. The windings of the transformers l3 and I4 may also be arranged in a twenty-four phase relationship in order that the alternating current transmitted to the circuit 2 is of suitable wave form. When the system is operating to transmit power at different predetermined current levels or within different ranges of current, the electric valve inverters 62 and fill may be selectively connected and disconnected to energize selectively primary windings l6 and i8, respectively, to transmit power to circuit 2 at substantially constant voltage, or within predetermined ranges of voltage, by controlling the resultant ampere-turns or the resultant magnetic field linking secondary windings 19 and of transformers I3 and M, respectively. The broad feature of transmitting power betweenconstant current, direct current circuits and constant voltage, alternating current circuits by arrangements of this nature is disclosed and claimed in a copending patent application Serial No. D-53,'786 of Frank R. Elder, filed concurrently herewith and assigned to the assignee of the present application. Excitation circuits 58 and the cathode heating elements for the electric valves 61 are energized from transformers 8|, 82, 83 and 84. Suitable phase shifting devices, such as rotary phase shifters 8588, are interposed between transformers Bl-B and circuits 69-12-to provide means for controlling the phase of the voltages impressed aacaiss on the control grids 89 of electric valves 0? and to provide thereby means for controlling and adjusting the amount of power transmitted to I the alternating-current circuit 2.

To control the amount of power transmitted to the alternating current circuit 2 at the difierent predetermined power levels demanded by the receiving station, I provide a circuit 00 comprising a frequency responsive means ti which selectively connects and disconnects predetermined electric valve inverters in the system. For example, the electric valve inverter 02 is provided with a short circuiting or shunting switch 02 and an alternating current isolating switch 93, and the electric valve inverter 64 is provided with short circuiting switches 04 and an alternating current isolating switch 95. The frequency responsive means 0i may be any suitable arrangement for effecting selective operation of the switches 02-0'd under varying load conditions. For example, as the load increases, the frequency responsive means connects the inverter 02 operatively in the system and, if the load increases still further, connects the inverter 00 operatively in the system. Of course, as the load decreases the reverse operation is followed.

The load to which the circuit 2 is connected may be represented by circuit A suitable switch 01 and a step -down transformer may be connected between circuit Z2 and the load 00, if desired.

As a means for supplementing the inverters iii-0d in the maintenance of the voltage and the frequency of the alternating current circuit 2 substantially constant under varying load conditions, I provide a synchronous dynamo-electric machine 90 having an armature member I00 and a field winding WI. The field winding i0l may be energized from any suitable source of direct current I02 through acurrent controlling means, such as an adjustable resistor or rheostat I03. In order to maintain the voltage and the frequency of the alternating current circuit 2'substantially constant in a system of this nature, it is important to vary or control the excitation of the synchronous machine 99 in response to the amount of load transmitted. That is, it is necessary to introduce into the circuit for the field winding IOI a component of unidirectional current which varies in accordance with or in response to the load current transmitted. To accomplish this control, I provide a current transformer I04 which furnishes an alternating current which varies in accordance with the load transmitted Current transformer I04 energizes a load compensating device I05 which transmits variable amountsof unidirectional current to the field winding IM to control the voltage and the frequency of the synchronous machine 99. The load compensating device I05 may comprise a rectifier I06 which may include a full wave electronic device I01 and a transformer I08 which are energized from any suitable source of alternating current I09. The anode-cathode voltage applied to the electronic discharge device I0! is controlled by means of a saturable reactor 0 having windings III connected in series relation with the transformer I08 and the source of alternating current I09. Thqsaturable reactor H0 is also provided with a control winding II2 which is energized by variable amounts of unidirectional current from a full wave rectifier II3 which in turn is energized by the current transformer I04. 'A suitable current controlling device, such as an adjustable resistance H0 may be con-= nected across rectifier M3.

The operation of the embodiment of my invention diagrammatically illustrated in Figs. la-ld will be explained by considering the system when it is operating to transmit power from the alternating current circuit l to the alternating current circuit 2 over the direct current transmission line 0. In this embodiment of my invention, power is transmitted at different predetermined values of voltage of the direct current circuit 3 or may be transmitted at difierent values or ranges of current and the amount of power transmitted is controlled by the number of transmitting and receiving units operatively connected to the direct current circuit 0. For example, the individual electric valve rectifying circuits or units 0-?! may be designed to supply a predetermined terminal voltage, such as 10,000 volts. When all units are connected operatively in series relation, the total voltage impressed across the direct current circuit 0 would, of course, be 40,000 volts. The frequency responsive device M at the receiving station controls the number of electric valve inverters which are operatively connected to the alternating current circuit 2 and thereby controls the amount of power transmitted to circuit 2. Let it be assumed initially that the system is operating at substantially 30,000 volts, that is, when power is being transmitted by rectifying units i, 0 and II. This condition of operation may be efiected by operating switch 50 so that'contact 50 is closed, thereby energizing switch 630 and efiectively shunting the direct current terminals 8 and 9 of rectifying unit 5. Under such conditions of operation, the frequency responsive device 0i would operate so that inverting unit 02 at the receiving station is effectively short clrcuited by means of switch 92, and therefore, power would be transmitted from the direct current circuit 3 to the alternating current circuit 2 through inverting devices 6|, 63 and 64. If it is desired to transmit a greater amount of power from circuit I to circuit 2, switch 58 may be operated so that contacts 59 and 60 are open, effectively connecting rectifying unit 62 in series relation with the other inverter units. The direct current voltage will, of course, be increased correspondingly to 40,000 volts. Upon application of additional load to circuit 2, the frequency of circuit 2 will temporarily decrease and the frequency responsive circuit 90 will operate to put electric valve inverter 62 in operation so that the increased amount of power may be transmitted. Conversely, the frequency responsive circuit 90 will effect a decrease in the number of units con-' nected if the power demand decreases. This action is brought about by the temporary rise in frequency of circuit 2 upon decrease in load.

of course, it is to be understood that the switch 58 may be made to operate in accordance with a predetermined controlling influence such as the ,power demanded by the direct current circuit 3.

The overload protection means 41 operates to move switches to the right-handposition and to bias the electric valves I4 to a 'nonconductive condition when the current tends to exceed a. safe operating value. I J

Power is transmitted to the alternating current circuit 2 at substantially constant voltage and frequency. The excitation of the synchronous machine 99, which may act as a synchronous condenser to supply variable amounts of reactive volt-amperes, is varied in accordance with the amount of power transmitted in order that the speed and the frequency of the machine shall remain within a predetermined range of values. The load compensating device I05 increases the energization of field winding IOI upon increase in load, thereby preventing an in-' crease in the frequency of the system. The load compensating device I05 transmits a variable component of unidirectional current to the field winding IOI in addition to the substantially constant unidirectional component of current supplied to the field winding from circuit I02. I have found that this arrangement is very satisfactory for controlling the voltage and frequency in systems where an alternating current circuit is energized from a direct current transmission line and where the load connected to the circuit is of the static type, that is, devoid of other synchronous generating equipment. 1

An important feature of the embodiment of my invention shown in Figt, la-ld, is the manner in which the power flow is, controlled by switching in and out certain polyphase groups of windings and the associated electric valve means. As stated above, transformers 25, 26, I3 and I4 are arranged to provide a twenty-four-phase system of voltages. At the transmitting station and the receiving stations, transformers,25, 26 and I3, 14, respectively, provide four six-phase systems displaced in phase with respect to each other. These groups of windings, by operation of the associated electric valve means, are placed in operation and taken out of operation to control the power and the current transmitted. When all the units are connected, the system operates as a twenty-four-phase system and, of course, as the units are disconnected in succession, the system operates as an eighteen-phase or a twelvephase system.

I have found that when the direct current transmission system of Figs. lat-1d operates as a substantially constant voltage direct current system that it is important to maintain a predetermined relationship between the volt-ampere characteristics of the transmitter and the receiving units. From a practical operating point of fiw, there are two kinds of stability to consider in maintaining the system in operation. First, the system must have what is generally termed a relatively high steady state power limit so that the intended amount of load may be transmitted. Second the system should be designed so that it rema s in operation under transient disturbances, such as disturbances occasioned by valve failure, short circuits or instantaneous open circuits of part of the system.

I have found that there is acritical relationship between the volt-amnere characteristic of the transmitter and the volt-ampere characteristic of the receiver which determines whether or not the system will remain in operation durih transient disturbances. This critical condit1on may be defined by saying that the receiver should be stiifer than the transmitter; that is, the change in the receiver voltage per unit of current should be less than the change in transmitter voltage per unit of current. This relationship may be expressed by stating that the slope of the volt-ampere characteristic of the inverter is less than the slope of the volt-ampere characteristic of the transmitter. Thus, if the system does not have the required stability under transient conditions, the remedy is to increase the eifective impedance of the transmitter. It

should be observed that this relationship is just the opposite to that which is desired in a synchronous alternating current transmission system where increased stabiltiy is obtained by increasing the stifiness of the transmitting unit. The reason for this difference is that the direct current transmission system employing rectifiers and inverters for transmitting power between alternating current circuits and direct current circuits involves an entirely different kind of stability than encountered in the operation of alternating current systems.

In order that the direct current transmission system remain in operation under transient conditions, it is important that at all times the inverter circuit be capable of carrying out the normal intended commutation function in order that power may continuously flow from the direct current circuit to the alternating current circuit through the inverter units. This relationship may be stated in another way. The desired performance of the inverter may be accomplished by assuring at all times an adequate alternating current voltage in the output circuits of the inverters to effect the desired commutation'between the various electric valve means. The synchronous condenser connected to the alternating current output circuit, or circuits, of the inverter units supplies the commutating voltage which is so essential to the proper operation of the system both under steady state conditions and under transient disturbances.

Figs. 2m and 2b together diagrammatically illustrate a direct current system for transmitting power between constant voltage alternating current circuits H5 and H6 through a direct current transmission line I IT. The system shown in Figs. 2a and 2b is capable of transmitting power in either direction between the constant voltage alternating current circuits H5 and H6, but for the purpose of explaining the invention the translating apparatus associated with circuit H5 will be considered as the transmitting station and the apparatus associated with the circuit H6 will be considered as the receiving station. A plurality of electric valve rectifying circuits H8 and I I9 are connected in series relation with each other and are connected to transmit direct current to circuit II'I. Each of the rectifying circuits H1 and 'I I8 is provided with a plurality of electric valve means I20, which are preferably of the type employing an ionizable medium and each of which comprises an anode I2I, a cathode I22 and a control member or grid I23. Connected between the alternating current circuit H5 and the electric valve rectifiers II 8 and H9, I provide a transformer I24 having a plurality of. primary windings I25 and two groups of secondary windings I26 and I2I which energize separate alternating current circuits I28 and I29, respectively.

To control the conductivity of the electric valves I20, I provide a plurality of excitation circuits I30. Only one of the excitation circuits I30 in rectifying circuits H8 and H9is shown in detail. It is to be understood that the other circuits are arranged in substantially the same manner. former I3 I a source of negative unidirectional biasing potential such as a battery I32, and a condenser I33 which is connected between the oathode I22 and the grid or control member I23 of the associated electric valve I20. In order to control the conductivity of the electric valves I to transmit power at a substantially constant voltage Each of the circuits I30 includes a trans-- power at substantially constant kilowatts when the load tends to exceed a predetermined value, I

within a predetermined range of power transfer and to effect a predetermined variation in the output characteristics of the valves to transmit provide a transformer I34 having primary windings E35 connected in series relation with the circuit i223 and having secondary windings iiit. The secondary windings I36 are provided with a plurality of taps I3? to adjust the magnitude of the control voltage obtained from circuit ltd. Transformer ltd operates essentially as a current transformer to provide a control voltage of predetermined phase and of a magnitude which varies in accordance with the current transmitted by the associated circuit. The control voltage derived from the transformer lid is introduced into excitation circuit 830 by means of a suitable impedance such as a resistance lid. The variable control voltage derived from transformer I 343 is combined with an alternating voltage of predetermined phase and magnitude by means of a transformer I39 having primary windings i413 and secondary windings MI and I42. The phase of the voltage introduced into excitation circuit by transformer I39 may be adjusted by means of a suitable phase shifting device, such as a rotary phase shifter I43. The rotary phase shifters I43 associated with the electric valve rectifiers H8 and H9 may be mechanically coupled. if desired. Adjustment of the rotary phase shifter I43 determines the value of power at which the transition from constant voltage to constant kilowatt operation takes place.

At the receiving station I provide a plurality of groups of serially connected electric valve inverters I44 and I45, each of which comprises a plurality of electric valve means I46 which are preferably of the type employing an ionizable medium. Each of the electric valves I46 comprises a control grid I41. The electric valve inverters I44 and I45 operate to transform direct current into alternating current and energize circuits I48 and I49, respectively. A transformer I50 is connected between circuits I43 and I49 and circuit H6 and comprises primary windings II and I52 and secondary windings I53. A plurality of suitable excitation circuits I54 are associated with each of the electric valves I 46 to control these electric valves for inverter operation, and each may comprise a transformer I55, 2. suitable source of negative unidirectional biasing potential such as a battery I58, and a capacitance I51 for absorbing voltages which may be present in the control circuits. The amount of power transmitted to the alternating current circuit II 6 is controlled by excitation circuits I54 which in turn are controlled by suitable phase shifting devices, such as rotary phase shifters I58 and associated transformers I59. Adjustment of the rotary phase shifters I58 controls the amount of power transmitted to circuit, IIB.

.The voltage and frequency of the alternating current circuit IIB may be controlled by an arrangement such as that disclosed above in connection with Figs. la-ld. More specifically, I may employ the synchronous dynamo-electric machine 99 and a control or load compensating device such as the device I05 described above in connection with Figs. la -1d.

The amount of power transmitted to the alternating current circuit H6 may be controlled by means of a suitable frequency responsive means I60 which controls the phase of the voltage impressed on the control grids I4'I of electric valve and frequency.

The embodiment of my invention shown in Figs. 2a and 2b operates to transmit power from the alternating current circuit H5 to the alternating current circuit H6 at substantially constant voltage for a predetermined range of power transfer and transmits power at approximately constant kilowatts when the power tends to exceed a predetermined value. This characteristic is obtained by the adjustment of the rotary phase shifters M3 at the transmitting station.

Prior to a consideration of the operation of the entire system, the operation of the individual excitation circuits lid will be considered. Fig. illustrates an operating characteristic of one of the electric valves I26 and the associated excitation circuit I30. Curve A represents the polar vector diagram of an electric valve of the type employing an ionizable medium for various angular displacements between the anode-cathode voltages and the grid voltages. Vector OB represents the voltage introduced into the excitation circuit I 39 by means of transformer I39, more particularly secondary winding I42, and vectors BC and BC represent the voltage introduced into the excitation circuit I by means of transformer I34 and resistance I38. Of course, it is to be understood that the magnitude of the vector BC varies in accordance with the load transmitted by the associated alternating current circuit I28 or in accordance with the current transmitted by the associated rectifying circuit II8. It will be noted that the resultant vector 00 which is impressed on the control grids I23 varies in phase with respect to the anode-cathode voltage repre- I sented by a vector lying along 00. So long as the resultant voltage represented by vector 00 leads the anode-cathode voltage, the electric valves transmit power at constant voltage to circuit I I I. But upon increase of the load current to a value sufiicient to retard the resultant grid voltage to a lagging position, such as that represented by the vector 00', the output voltages of the electric valves I20 and hence the voltages of the rectifying circuits I I 8 and I I 9 are decreased in accordance with the polar diagram. It will be appreciated that the rectifying circuits I I8 and H9 transmit power at substantially constant voltage until the current or the load exceeds a predetermined value at which point the rectifying circuits begin to transmit power in accordance with a difierent characteristic which simulates a constant kilowatt characteristic. Adjustment of the rotary phase shifters I43 permits control of the value of power at which the transition from the constant voltage characteristic to the constant kilowatt characteristic occurs.

Fig. 2d diagrammatically illustrates the output characteristic of the transmitter station. Curve E represents the constant voltage output characteristic and curves F, G, H and J represent the modified output characteristic when the load tends to exceed a predetermined value. Points K, L, M, and N represent the values of load current at which the transition occurs between the constant voltage output characteristic and the constant kilowatt or power output characteristic. Selection of these points or intermediate points, of course, may be obtained by positioning of the constant voltage within predetermined ranges of power transfer. Upon application of load, the frequency responsive means I60 operates the rotary phase shifters I58 to cause the electric valve inverters to transmit a larger amount of power. The synchronous dynamo-electric machine 99 serves to restore the voltage and frequency to the predetermined desired values.

Figs. 3a-3b, considered jointly, diagrammatically illustrate another embodiment of my invention as applied to a high voltage direct current transmission system. In the arrangements shown in Figs. Bit-3b, electric power is transmitted at different predetermined values of current over the direct current transmission line I6I. The value of the direct current which is maintained in the circuit I6I may be controlled or adjusted in accordance with load requirements. The system shown in Figs. 30-31) may be defined as a variable current-level direct current transmission system. In this arrangement, the transmitting and receiving units are connected in series relation. At the transmitting station serially connected rectifying electric valve apparatus I62--I65 are connected in series relation with each other. Each of the rectifying apparatus I62-I65 comprises an electric valve rectifier each including a plurality of electric valves I66 and each valve being provided with a control grid I61 for controlling the conductivity thereof. The electric valve rectifiers I82I65 each include direct current terminals I68 and I69 which are connected to the direct current circuit I6I. An alternating current circuit I70 energizes the electric valve rectifiers I62I65 through transformers Ill-I14 and through switches I15-I'I8, respectively. The air core inductive reactances I19 may be connected in series relation with the electric valve rectifiers I62I65 to act as current smoothing reactances. The alternating current circuit I10 may be energized by means of a synchronous dynamo-electric machine I having an armature IN and a field winding I82. A switch I80 may be connected between the circuit I10 and machine I80.

As a means for controlling the excitation of the dynamo-electric machine I80 to maintain difierent predetermined current levels in the direct current circuit I6I, I provide a suitable current regulator I83 which may be a conventional arrangement well known in the art, and for the purposes of illustration I have represented it as comprising an exciter I89 having an armature I85 and a field winding I85, a sub-exoiter I81 having an armature I88 and a field winding I89, and a vibratory contact regulator I98 having an actuating winding I 9| and an anti-hunting coil I92 which is energized in accordance with the armature voltage of the subexciter I81. The actuating coil I9I of the regulator I may be energized in accordance with a predetermined electrical condition which varies as the current of the direct current circuit I6I. For example, I connect a suitable shunt I93 in series relation with the direct current circuit I6I, and the voltage appearing across the shunt I93 is impressed across the terminals of the coil I9I.

As an agency for selecting the current level at which power is transmitted over the direct current circuit I6I and for controlling the current level in accordance with the power demanded by the transmission system, I provide a regulator circuit I 95 which may include a wattmeter I95 having direct current terminals I96 connected to be energized in accordance with the current transmitted by circuit I8I and terminals I96 energized in accordance with the potential of the direct current circuit I6I. The terminals I91 may be energized through associated apparatus (not shown) connected to the direct current circuit I6I to efiect a desired reduction in the value of the voltage applied to the wattmeter I95. The wattmeter I95 is provided with a movable member or contact I91 which engages contacts I98-20I, each of which represents a predetermined range of power transfer. Relays 202205 are controlled by the wattmeter I95 and control the effective value of the shunt I93 which is connected in series with the circuit I6I. The relays 202-205 may be energized from a suitable source of current, such as a battery 206, through a switch 201. The relays 202-205 control the current level which is maintained in the direct current circuit I8I in accordance with the power transmitted by the system.

I provide means for selectively connecting and disconnecting the electric valve rectifying circuits ISL-I68 to the direct current circuit I6I in accordance with the power demanded by the system. More specifically, I provide contactors 208, 209 and 2l0 which are associated with the direct current terminals I68 and I69 of electric valve rectifiers I62-I64,respectively, and which connect and disconnect the rectifiers to the circuit IBI in response to the power transmitted by the system. The electric valve rectifiers I62-- I69 may be arranged to be connected and disconnected in any predetermined order to satisfy load requirements. One way in which the rectifiers I62-I69 may be connected is that in which the rectifiers I62I69 are connected in sequence and are disconnected in the reverse order. Contactors 208-2I0 are arranged to short circuit the direct current terminals in the order named and to open circuit the terminals in the reverse order. Contactors 208--2I0 are provided with relays 2II2I3, respectively, which control the energization of the actuating coils for contactors 208--2i0 so that this sequence is followed. Time delay relays 2M may be connected in series relation with the actuating coils of contactors 209 and 2H] and relays M2 and H3 to prevent hunting between the control circuits and to prevent simultaneous operation of contactors 208-2I0. Only one of the time delay relays 2M is shown in detail. It is to be understood that any suitable time delay arrangement may be used.

A relay M5 is provided to control the energization of contactors 208-2I0 and relays 2I I-2I3 to effect connection and disconnection of the rectifiers I62-I6tl in response to a predetermined controlling influence which varies as the power transmitted by the system. The relay MS may be of the contact-making voltmeter type having an actuating coil 2I6 and contacts 2!! and 2I'8. Armature member 2I9 is spring biased against a predetermined pull of coil 2I6 to the intermediate position. The relay 2I5 may be energized in accordance with the armature voltage of the sub-exciter I81 to control the number of rectifiers effectively connected to the direct current circuit I 6|. The armature voltage of the subexciter I81 varies in accordance with the power transmitted by the system and may be employed to effect this sclective operation of the contactors 208-2") When'contacts MB of the relay 2I5 are closed, indicating a decrease in the power transmitted by the system, one of the contactors of contactors 208-2"! is operated to shunt the direct current terminals of the associated rectifiers l62-l'64, and when the contacts 2|! are closed, one of the contactors 268-2) is operated to connect the associated rectifiers to the direct current circuit l6l. Of course, upon sudden decreases and increases of load, it is to be understood that "two or three of the rectifiers may be controlled in rapid succession in order to meet the load requirements.

In order to protect individual rectifiers I62- l64 from overload, I employ a circuit 220 which may be of the type discussed above in connection with Figs. 2a and 21). Upon overload, the phase of the voltages impressed on the control grids I6"! is retarded to decrease the amount of current transmitted irrespective of the control indicated by the other associated control apparatus. The circuit 226 is energized from a plurality of current transformers 22l and includes a transformer 222 having primary windings 223 and secondary windings 224 which introduce into circuit 220, by means of resistances 225, voltages which vary in magnitude in accordance with the current transmitted by the alternating current circuit I10. A voltage of predetermined phase and of constant magnitude is also introduced into the circuit 220 by means of a transformer having primary windings 226 and secondary windings 221. The phase of the voltage of constant magnitude may be adjusted by any suitable arrangement such as a rotary phase shifter 228. It is to be understood that rectifiers l63-I65 may also be provided with current limiting or controlling circuits 220.

At the receiving station I provide a plurality of serially connected electric valve inverters 229-232, inclusive,'each of which comprises a plurality of electric valve means 233 which are preferably of the type employing an ionizable' medium and having a control member or grid 233. The electric valve inverters 229-232 are arranged to be selectively connected in operative relation for the transfer of power by means of contactors 234-236 and control relays therefor 231-239, respectively. Power is transmitted from the direct current circuit "ii to an alternat ing current load circuit 240 through the electric valve inverters 229-232. The electric valve translating system connected at the receiving station functions to transmit power at substantially constant voltage to the alternating current circuit 246 irrespective of the current level at which power is transmitted over the direct cur rent circuit l6l. The amount of power transmitted to circuit 240 is controlled by the number of inverting units 229-232 which are connected in operative relation. As a means for controlling the power, voltage and frequency of the alternating current circuit 240 within the ranges of power transfer determined by the number of inverter units connected to circuit HI, I provide an auxiliary or supplementary electric valve circuit 24! which is capable of operating either as a rectifier or as an inverter for the transmission of power between the direct current-circuit I" and the alternating current circuit 240. The electric valve circuit 2 comprises a plurality of electric valve means 242 which may alsobe cf the type employing an ionizable medium, such as a gas or a vapor, and each comprises a control grid 243 which controls the conductivity of the electric valves and also determines the operation of the circuit as a whole.

I provide inductive networks, such as transformers 244 and 245, which are connected between electric valve inverters 229, 236 and 23!, 232, respectively, and the alternating current circuit 240. The electric valve inverters control the resultant ampere-turns or the resultant magnetic field of the transformers and thereby control the power transfer between circuits [6! and 240. Transformer 244 is provided with a plurality of primary windings 246 and 241 which are connected to electric valve inverters 229 and 236 through switches 248 and 249, respectively. Transformer 244 is also provided with a secondary winding 256 which is connected to the alternating current circuit 246. Likewise transformer 245 is provided with a plurality of primary windings 25f and 252 which are associated with electric valve inverters 23l and 232 through switches 253 and 254, respectively. Transformers 244, 245 may be connected in a twenty-four phase system in a manner similar to transformers 25 and 26 of Figs. lw-ld. That is, each of transformers 244, 245 may provide a six-phase system of voltages displaced in phase from each of the other six-phase systems of the other transformers. Transformer 245 is also provided with a secondary winding 255 connected to the alternating current circuit 246. A transformer 256 and a switch 257 may be connected between the auxiliary electric valve circuit 24f and circuit 240. In addition, a transformer 258 and a suitable switch 259 may be connected in the alternating current circuit 246 to disconnect the load from the electric valve circuits 229-232 and circuit 246.

The electric valves 233 of the inverters 229- 232 operate as inverters and are controlled by means of a plurality of control circuits. Only one of the control circuits associated with an electric valve in inverter circuit 232 is shown. It is to be understood that these circuits are similar in construction and arrangement and operate to control the electric valve inverters to transform direct current into alternating current. By way of example, I may employ a circuit 266 which is similar in many respects to control circuit 33 described above in connection with Figs. la-ld. Corresponding elements have been assigned like reference numerals. The transformer 38 may be energized from a suitable source of alternating voltage 26! through any suitable phase shifting arrangement, such as a rotary phase shifter 262. It is to be understood that the other electric valves in the inverter group 232 are energized from the output circuit of the rotary phase shifter 262. Furthermore, it is to be noted that each of the other inverter circuits 229-238 may also be provided with similar excitation systems to control the amount of power transmitted by the respective inverter circuits. The rotary phase shifters 262 can be operated severally or jointly.

I provide a dynamo-electric machine 263 of the synchronous type for controlling the voltage of the alternating current circuit 240 within narrowly defined limits. The machine 263 may comprise an armature 264 and a field winding 265 which is energized from any conventional system such as a voltage regulator 266 comprising an exciter 267, a sub=exciter 266, a resistance 269 which is intermittently shunted by means of contacts 216 to control the excitation of the subexciter and hence the excitation of the exciter and field winding 265, and an alternating current actuating coil 2'" and an anti-hunting coil 212. It is to be understood that I may employ any other conventional arrangement well known in the art for controlling the energization of the field winding 265 in accordance with a predetermined controlling influence such as the voltage of circuit 240.

I provide a frequency responsive circuit 213 which controls the auxiliary electric valve circuit MI and also controls the number of inverter circuits which are connected in operative relation for the transfer of power between circuits NH and 240. The circuit 213 also, of course, controls the voltage within certain limits. Circuit 213 may comprise a transformer 21 a suitable phase shifting arrangement such as a rotary phase shifter 215 and a transformer 216 connected between the rotary phase shifter 215 and the grid circuits for electric valves 262 in circuit 2M. In addition, the rotary phase shifter 215 is provided with a movable contact 211 and stationary contacts 218 and 219 which in the extreme positions of movement of the contact 211 control relays 231239 and contactors 23-236 to control the number of inverters operatively connected in the system. Of course, the rotary phase shifter 215 controls the amount of power transmitted to circuit 245 and hence controls the voltage and frequency of circuit 245.

To control the position of the rotary phase shifter 215, I employ any suitable arrangement such as a reversible motor 280 having field windings 2M and an armature 282 and a relay 283 having an actuating coil 286. The position of the movable element of the rotary phase shifter 215 and hence the phase of the voltage impressed on the control grids 283 of valves 244 is controlled by means of a frequency sensitive network 285 which may comprise a resonant circuit including a capacitance 286 and an inductance 281. The resonant circuit may be energized through a transformer 288. Variable amounts of current v are transmitted to the actuating coil 28$ from circuit 250 by means of a full wave rectifier 289 and a serially connected saturable inductive reactance 290.which is controlled by means of a rectifier 29I which is energized in accordance with the voltage appearing along the inductance 281 in the resonant circuit. The resonant circuit may be tuned to a frequency slightly greater than the frequency which is to be maintained so that as the frequency varies from the predetermined value to be maintained, the energization of coil 286 is varied to effect movement of the rotary phase shifter 215 in the proper direction.

Prior to the explanation of the manner in which the embodiment of my invention shown in Figs. 30-31) operates, it is emphasized that the system there disclosed permits transfer of power over a direct current transmission circuit at different predetermined current levels. While the system is operating within these current levels, the current throughout the system is maintained at a substantially constant value, and the variations in power d mands are met by variations in the value of t e voltage of the direct current circuit. In addition, it is emphasized that the value of current maintained in the direct current circuit may be adjusted or controlled, either automatically or manually, to control the current level at which power is transmitted in order that the power losses of the associated equipment may be reduced substantially when the power demanded is not large. Furthermore, the current level may be substantially increased to meet the power demands when the power required by the system is relatively large.

For every current level at which power is transmitted over the direct current circuit IBI, the dynamo-electric machine I maintains a corresponding alternating current of constant value in circuit I10, and the electric valve rectifiers ISL-I65 transform the alternating current of constant value into direct current of constant value. The electric valve inverters 229-232 at the receiving station transform the direct current of constant value into alternating current of constant value. These inverters transmit a1- ternating current of constant value to the primary windings of transformers 244 and 255 and control the resultant magnetic field of these transformers so that power is transmitted to circuit 25!] at substantially constant voltage. Of course, the dynamo-electric machine 263 and the auxiliary electric valve circuit 2M also operate to control voltage within certain regions.

In explaining the operation of the system under varying power demands, the transmitting station will be considered first. The transmitting station is arranged to satisfy the power demanded by the system and is arranged to transmit power at different predetermined current levels in order to maintain the power losses at a relatively low value over a wide range of load. Of course, such control maintains the efliciency of the system at high values irrespective of the amount of power being transmitted. Let it be assumed that the power demanded by thesystem is relatively small and that only electric valve rectifier I65 is required to supply power to the direct current circuit I6I. Circuit I94 operates in response to the power to control the current level at which power is transmitted and for the particular value of power being delivered, the movable contact member I91 of wattmeter I95 may be assumed to be in the position indicated. The current regulator I83 controls the excitation of the dynamo-electric machine I80 to maintain constant current in circuit I10 and the electric valve rectifier I65 transforms the alternating current of constant value into direct current of constant value, The voltage appearing across the shunt I93 controls the energization of coil I9I of regulator I83 to eifect this result. It will be understood that within the predetermined range of power established by the circuit I95. power is transmitted at a constant current level and the variations of power within this range are met by changes in the value of the output voltage of rectifier I 65, or, in other words, changes in the direct current voltage of circuit iBI. Under this condition of operation where only electric valve rectifier I65 is in operative relation, it is understood that rectifiers ISL-I54 are controlled by means of contactors 268 2I0 which shunt the direct current terminals of the rectifiers.

If it be assumed that the power demanded by the system increases beyond the amount of power which may be supplied by rectifier I65, electric valve rectifier I62 will be connected in circuit by operation the contactor 208 which in turn is controlled by relay 2 and the relay 2I5. Relay 2|5 is controlled in response to the power transfer and is directly responsive to the armature voltage of the sub-exciter I81. Within this range of power transfer, electric valve rectifiers I52 and I 65- transmit power at the pre- 

